OPTICAL GUIDED WAVES AND DEVICES Richard Syms John Cozens Department of Electrical and Electronic Engineering Imperial College of Science, Technology and Medicine McGRAW-HILL BOOK COMPANY London New York St Louis San Francisco Auckland Bogota Caracas Hamburg Lisbon Madrid Mexico Milan Montreal New Delhi Panama Paris San Juan Säo Paulo Singapore Sydney Tokyo Toronto
CONTENTS Acknowledgements ix 1. Overview 1 1.1 Guided wave optical devices 1 1.2 Rationale 7 2. Electromagnetic fields and plane waves 9 2.1 Maxwell's equations 9 2.2 The differential form of Maxwell's equations 15 2.3 Harmonically-varying fields and the wave equation. 17 2.4 Plane waves 19 2.5 Power flow 27 2.6 The propagation of general time-varying signals 30 3. Material effects 37 3.1 Introduction 37 3.2 The origin of the dielectric constant 38 3.3 Material dispersion 42 3.4 The origin of electrical conductivity 45 3.5 Anisotropic media 49 3.6 Non-linear effects 55 3.7 The electro-optic effect 57 3.8 Stress-related effects 65 4. The optics of beams 72 4.1 Scalar theory 72 4.2 Spherical waves 72 4.3 Lenses 76 4.4 Diffraction theory 80
VI CONTENTS 4.5 Fraunhofer diffraction 82 4.6 Fresnel diffraction and Gaussian beams 84 4.7 Transformation of Gaussian beams by lenses 88 4.8 Mirrors and resonators 92 5. Reflection and refraction at a single interface 100 5.1 The behaviour of light at a dielectric interface 100 5.2 Superposition of fields 101 5.3 Boundary matching 103 5.4 Electromagnetic treatment of the interface problem 105 5.5 Modal treatment of the dielectric interface problem 114 5.6 Surface plasma waves 115 6. The slab waveguide 120 6.1 Guided waves in a metal guide 120 6.2 Guided waves in a slab dielectric waveguide 122 6.3 Other types of mode 129 6.4 The weak-guidance approximation 132 6.5 The orthogonality of modes 134 6.6 The power carried by a mode 136 6.7 The expansion of arbitrary fields in terms of modes 137 6.8 Application of the overlap principle 138 7. Planar waveguide integrated optics 145 7.1 Overview of planar waveguide components 145 7.2 Phase matching at a single interface 145 7.3 The FTIR beamsplitter 148 7.4 The prism coupler 150 7.5 Phase matching for guided modes 155 7.6 Refractive optical components 157 7.7 Gratings 161 7.8 Gratings in guided wave optics 169 8. Optical fibres and fibre devices 179 8.1 Optical fibre types 179 8.2 Loss in silica and fluoride glass fibre 181 8.3 Step-index optical fibres 182 8.4 Parabolic-index optical fibres 187 8.5 Signal dispersion 195 8.6 Mode conversion in fibres 197 8.7 Coupling to fibres 200 8.8 Fibre interconnects 204 8.9 Fibre-based components 209
CONTENTS VÜ 9. Channel waveguide integrated optics 217 9.1 Channel waveguide types 217 9.2 Input and output coupling 222 9.3 Sources of propagation loss 224 9.4 Polarizers 227 9.5 Mirrors 228 9.6 Tapers and Y-junctions 231 9.7 Phase modulators 235 9.8 Frequency shifting and high-speed operation 239 9.9 Interferometers 243 10. Coupled mode devices 250 10.1 Introduction 250 10.2 The directional coupler basic principles 250 10.3 The directional coupler theoretical analysis 253 10.4 Solution of the equations at synchronism 257 10.5 Asynchronous solution 258 10.6 Fibre directional couplers 260 10.7 Coupling between dissimilar waveguides 263 10.8 Sidelobe suppression using tapered coupling 266 10.9 The reflection grating filter basic principles 267 10.10 The reflection grating filter theoretical analysis 270 10.11 Solution of the equations at synchronism 272 10.12 Asynchronous solution 273 10.13 Fibre gratings 274 10.14 Other coupled mode interactions 275 11. Optoelectronic interactions in semiconductors 282 11.1 Wave-particle duality 282 11.2 Photons 284 11.3 Electrons 287 11.4 Band theory 295 11.5 Effective mass 304 11.6 Carrier statistics 307 11.7 Intrinsic and extrinsic semiconductors 311 11.8 Detailed balance 316 11.9 Rate equations 318 12. Optoelectronic devices 326 12.1 The p-n junction diode 326 12.2 Electro-optic semiconductor devices 339 12.3 Photodiodes 341 12.4 The light-emitting diode 346 12.5 The semiconductor laser: basic operation 356 12.6 The semiconductor laser: steady-state analysis 366
viii CONTENTS 12.7 The semiconductor laser: modulation 371 12.8 DBR and DFB lasers 373 12.9 Array lasers 378 12.10 Surface-emitting lasers 383 12.11 Travelling-wave laser amplifiers 385 13. Optical device fabrication 390 13.1 Overview 390 13.2 Planar processing 390 13.3 Substrate growth and preparation 391 13.4 Deposition and growth of material 393 13.5 Material modification 401 13.6 Etching 406 13.7 Lithography 411 13.8 Optical fibre fabrication 417 14. Systems and applications 428 14.1 Introduction 428 14.2 The planar integrated optic RF spectrum analyser 428 14.3 The planar integrated optic disc read head 432 14.4 Guided-wave optical chip-to-chip interconnects 433 14.5 The channel waveguide integrated optic A-to-D converter 434 14.6 Optical fibre sensors 437 14.7 The integrated optic fibre gyroscope 439 14.8 High-speed, guided wave optical communications 442 14.9 Fibre lasers and amplifiers 447 Answers to selected problems 453 Subject index 492